Integrated carry-on baggage cart and passenger screening station

ABSTRACT

The present invention is directed toward an integrated security checkpoint that can screen both individual passengers and carry-on carts containing their baggage. The methods, apparatuses, and systems of the present invention enable the efficient scanning of both individual passengers and their respective carry-on carts in the same secure area by providing individual passengers with a novel screening cart, permitting passengers to send the screening cart through an X-ray imaging machine, and permitting passengers to walk through an adjacent metal detector where, once cleared, the individual passenger can retrieve his or her screening cart.

FIELD OF THE INVENTION

The present invention relates to an apparatus for, and a method of, securing a location. More specifically, the present invention is a method, apparatus, and integrated system for screening of individual passengers and their corresponding carry-on baggage carts with improved throughput, efficiency, and quality. The present invention also relates to a carry-on baggage cart specifically designed for the disclosed integrated carry-on baggage cart and passenger screening system of the present invention.

BACKGROUND OF THE INVENTION

Locations must often be secured to ensure public safety and welfare. For example, places where there are large concentrations of people, such as airports or entertainment events, places that are of particular governmental importance, such as courthouses and government buildings, and other places where the threat of violence is high, such as prisons, require security measures to thwart dangerous or illegal activities. The primary security objective is to prevent the unauthorized entry of weapons, dangerous materials, illegal items, or other contraband into the location, thereby securing it. This is often achieved by requiring all people and items to enter into the location through defined checkpoints and, in those checkpoints, subjecting those people and items to thorough searches.

Currently, various devices are used to perform such searches. Regardless of the place of use, these detection systems are employed to detect the presence of contraband on the body or luggage of individuals entering the secure area. Contraband is not limited to weapons and arms. It includes explosives (fireworks, ammunition, sparklers, matches, gunpowder, signal flares); weapons (guns, swords, pepper sprays, martial arts weapons, knives); pressurized containers (hair sprays, insect repellant, oxygen/propane tanks); poisons (insecticides, pesticides, arsenic, cyanide); household items (flammable liquids, solvents, bleach); and corrosives (acids, lye, mercury).

Such conventional security systems rely on data individually recorded by each security device to evaluate the performance of the specific device. For example, a metal detector with an embedded counter records and stores the number of people that passed through the metal detector in a given period of time. Similarly, a baggage screening X-ray machine records the number of bags passed through the system and the number of bags that possibly contained contraband.

Screening checkpoints used in current security systems predominately operate using a single input and single output line approach. Each item must be thoroughly and individually scanned in the conventional systems. The complex security protocols being instituted require individuals to have each of their belongings, including laptops, shoes, coats, mobile phones, keys and other items, scanned by an X-ray scanner. It takes a considerable amount of time for individuals to divest themselves of their belongings and to remove laptops from their cases. This divestiture process tends to happen serially with individuals waiting in line until they have access to the machine. Contributing to the lag associated with the divestiture process, current systems employ a single conveyor belt, upon which each of the individual passenger items must be placed in order for the items to pass through the x-ray machine. Once the items are scanned, they accumulate on the opposite side of the scanning machine, thus creating “traffic” on the belt until retrieved by the passenger/owner. The belt must often be stopped by the operator to prevent the backlog of unclaimed baggage from reversing into the x-ray machine.

U.S. Pat. No. 6,472,984, assigned to Georal International Ltd., discloses a method of restricting access to an area comprising the steps consisting of: a) providing a chamber having one or more first doors and one or more second doors; b) opening said first doors to allow a person entry to the chamber from an infeed area; c) sensing for contraband as the person enters the chamber; d) if no contraband was sensed during entry to the chamber, closing the first door and opening said second door to allow the person access to the protected area, but if contraband was sensed maintaining said second door closed and allowing the first doors to open to provide access from the chamber to the infeed area; and e) detecting the presence of objects remaining in said chamber after the person has vacated the chamber, and inhibiting opening of at least one of said doors if an object is detected in said chamber.

U.S. Pat. No. 6,484,650, assigned to Gerald Stomski, describes a security system for monitoring and protecting personnel in an area including at least one queue of successively arriving individuals, comprising: a plurality of at least three contiguous chambers, including an entry chamber, an exit chamber and at least one intermediate chamber, wherein said chambers are arranged in a matrix of at least two parallel lines of chambers so as to receive at least two parallel queues of successively arriving individuals, said chambers each having bullet-proof transparent walls and bullet-proof doors, said doors including: an entry door to the entry chamber, an exit door from the exit chamber, a common door between each intermediate chamber and a said contiguous chamber, said doors having remotely controlled locks, means for monitoring a selected individual in a selected chamber, and an automated door interlock system arranged and adapted to remotely unlock selected locks to pass individuals successively through said chambers, and to lock selected locks to detain selected individuals during monitoring.

U.S. Pat. No. 6,308,644, assigned to Willian Diaz, discloses an access control vestibule, comprising; a vestibule frame configured to form said access control vestibule mounted in said vestibule frame; an entrance door and an exit door; an entrance door frame and an exit door frame; a panel mounted in said vestibule frame and forming a side wall section of said vestibule; said entrance door and said exit door being formed by a panel mounted in each of said door frames; locks associated with said entrance door and said exit door; a metal detector located to detect a metal object being disposed between said entrance and exit doors; control means to prevent both doors from being unlocked at the same time, and to prevent said exit door from being unlocked when said metal detector detects a metal object; said entrance door and said exit door both being manually operated; and said entrance door and said exit door each being formed by a single swinging door, and swingable towards the outside of said vestibule.

U.S. Pat. No. 4,357,535, assigned to Scan-Tech Security, L.P., discloses an apparatus for inspecting an article. More specifically, the '535 patent describes an inspection system to simultaneously X-ray inspect hand carried articles and provide metal detection of the person of the carrier. These different inspections are independent, and may be carried out separately from one another. The X-ray inspection involves the insertion of a hand carried item into a chamber, and guiding it along the X-ray inspection station by holding a handle outside of the detector. Metal detection of the person may be accomplished independently by walking through a metal detector arch.

The conventional prior art security baggage and passenger screening systems described above are inefficient in the manner in which they are set up to receive and distribute both passengers and their carry-on baggage. As mentioned above, the security protocols of conventional prior art screening systems require individuals to have each of their belongings, including laptops, shoes, coats, mobile phones, keys and other items, scanned by an X-ray scanner. It takes a considerable amount of time for individuals to divest themselves of these belongings. This divestiture process tends to happen serially with individuals waiting in line until they have access to the machine. Thus, X-ray machine operators spend more time waiting for passengers to divest themselves of their belongings and load them onto the conveyor than scanning bags.

In addition to the lag associated with the divestiture process, current systems employ a single conveyor belt, upon which each of the individual passenger items must be placed in order for the items to pass through the x-ray machine. Once the items are scanned, they accumulate on the opposite side of the scanning machine, thus creating “traffic” on the belt until retrieved by the owner. The resultant scanned baggage belonging to passengers that have been selected for additional hand searching wait at the X-ray system's exit conveyor until those passengers are thoroughly searched. Thus, the bags are left on the conveyor for approximately at least 1.5-2.0 minutes, thereby causing a back-up that forces the X-ray machine operator to have to wait until such back-up is cleared. The belt must often be stopped by the operator to prevent the backlog of unclaimed baggage from reversing into the x-ray machine.

Thus, even when individual passengers have access to the machine, the process is still time-consuming as each individual item to be scanned must be placed on the single conveyor belt and then collected by the owner. In addition, it may take some time for a passenger to reclaim and collect his baggage and other personal belongings, further creating backlog in the x-ray system. In addition, such existing systems tend to have many other problems, including for example, several security personal having excessive downtime and a necessity for a dedicated operator for each detector to direct traffic.

Additionally, passengers lack sufficient information regarding how to most efficiently pass through a baggage checkpoint or screening station. For example, passengers may wait in an X-ray lane full of passengers while a second lane remains completely empty, thereby causing unnecessary delay. Thus, the much desired streamlined and efficient function of the scanning operation is hampered. Current systems lack appropriate means for indicating whether lanes, among a plurality of check station lanes, are operational or closed.

Furthermore, passengers lack information regarding what items should be subjected to x-ray scanning, metal detection, or hand searching, such as large buckle belts or shoes. The presence of portable computing devices, such as laptops, further causes more delay. It takes a considerable amount of time for individuals to remove laptops from their cases. Generally, as described above, portable computing devices must be removed from their carrying case and placed into bins or drawers so that they can be scanned singularly. Passengers often fail to efficiently remove such items from their carrying cases and, consequently, do not efficiently proceed through the X-ray scanning checkpoint efficiently. Individual passengers thus wait in line until they have access to the machine.

Additionally, those areas contained within the scanning checkpoint or check station areas specifically allocated for passengers to divest themselves of their belongings are not set up to facilitate rapid and efficient divestiture of passenger belongings. In conventional systems, such areas consist of tables located in front of or around the conveyor belt scanner, thus causing those slower passengers to block the line from moving at a reasonable and efficient pace. Along the same lines, the problem also presents itself when passengers collect their belongings and reload their items and replace portable computing devices in their cases. Individual passengers also lack proper instruction on where to stand so as not to obstruct the natural flow of the X-ray scanning system line.

Conventional security screening systems lack appropriate means for handling carry-on baggage in its entirety prior to and/or during scanning. Traditional carry-on baggage carts are cumbersome and bulky in dimension, including towable, portable, or mobile carts. These carry-on baggage carts present problems when scanned in conventional scanning systems. For example, the design of the carts does not allow for conventional scanning systems to sufficiently scan due to the inadequate positioning of the carry-on baggage. This, in turn, leads to the capturing, storing, processing and development of incomplete and imprecise X-ray images. In addition, the carry-on luggage carts require a larger X-ray apparatus to be scanned completely. Metal bars of existing cart designs may also hinder the path of the X-ray, thus obscuring some of the items placed on the cart from scanning. This also leads to imprecise capturing, storing, processing and development of x-ray images. In addition, in scanning conventionally designed carry-on baggage carts, it is difficult to contain the x-ray radiation; to scan an existing, conventional carry-on baggage cart, the x-ray machine would need a very large opening. Thus, in such systems, costly safeguards would need to be implemented to protect the general public and x-ray operators.

Despite these prior art efforts to improve methods, apparatuses, and systems for scanning carry-on baggage, the abovementioned problems have not been solved. The prior art methods fail to disclose methods and systems that alleviate delay during the divestiture process. In addition, the prior art does not improve the overall efficiency and throughput of the system.

There is a need for an improved security check station that reduces the waiting time for individuals and has improved throughput and efficiency. Such a system would reduce over-staffing of security personnel, facilitate automation of the metal detector, curtail idle time of x-ray machine operators, and significantly increase throughput of the machines due to decreased back-up of the conveyor system. In a scanning system with improved throughput and efficiency, it is possible to reduce the total number of scanning stations required at any one location. In addition, with shorter lines of people waiting for baggage and body scans, less floor space is required.

Additionally, there is a need for methods or systems of integrating data from multiple security devices dynamically and communicating such data to a plurality of users, in order to enable effective security. In particular, there is a need for integrating scan data from individual passenger scans with carry-on cart data from such a screening system to correlate the data.

There is also a need for an intelligently managed security system, where the plurality of information is centrally processed for yielding specific outputs to different users. Also, there is a need to correlate the scanning data of different entities to improve the security level.

SUMMARY OF THE INVENTION

The present invention is directed toward an integrated security checkpoint that can screen both individual passengers and carry-on carts containing their baggage. The methods, apparatuses, and systems of the present invention enable the efficient scanning of both individual passengers and their respective carry-on carts in the same secure area by providing individual passengers with a novel screening cart, permitting passengers to send the screening cart through an X-ray imaging machine, and permitting passengers to walk through an adjacent metal detector where, once cleared, the individual passenger can retrieve his or her screening cart.

In one embodiment, the present invention is directed towards a method for conducting security comprising the steps of providing a person to be screened with a screening cart wherein the screening cart is an assembly designed to physically complement an X-ray scanning system; providing a guide mechanism that physically engages the screening cart wherein the guide mechanism directs the screening cart through an X-ray scanning system; and delivering the screening cart to the passenger. The method further includes directing a passenger to walk through a passenger to walk through a passenger screening device. In one embodiment, the passenger screening device is a metal detector. In another embodiment, the passenger indicates that the passenger is ready to be screened.

In a preferred embodiment of the method for conducting security, the screening cart comprises a “C”-configuration assembly. Preferably, the “C”-configuration assembly screening cart further comprises a substantially connected frame assembly having a substantially rectangular base; a substantially rectangular drawer; and at least two wheels. Preferably, the substantially rectangular base and substantially rectangular drawer are integrally connected with a vertical arm to form a “C”-shape assembly. Preferably, the cart is comprised of a metallic material, such as stainless steel and/or aluminum.

In a preferred embodiment of the method for conducting security, the X-ray scanning system comprises a radiation source and a detector array. The radiation source is a dual energy source. In one embodiment, the entrance of the X-ray source is a C-frame structure.

In another embodiment, the present invention is directed towards a system for conducting security, comprising an X-ray scanning system which further comprises an entrance designed to physically complement, or physically receive, a screening cart assembly; a guide mechanism to direct a screening cart passing through the X-ray scanning system; and a mechanism for delivering the screening cart to the passenger after both passenger and cart have been screened. Preferably, the X-ray scanning system comprises a radiation source and a detector array. The radiation source is preferably a dual energy source. In one embodiment, the entrance of the X-ray source is a C-frame structure. In one embodiment, a passenger screening device, such as but not limited to a metal detector, is provided.

In a preferred embodiment, the screening cart comprises a “C”-configuration assembly. Preferably, the “C”-configuration frame assembly screening cart further comprises a substantially connected frame assembly having a substantially rectangular base; a substantially rectangular drawer; and at least two wheels. Preferably, the substantially rectangular base and substantially rectangular drawer are integrally connected with a vertical arm to form a “C”-shape assembly. Preferably, the cart is comprised of a metallic material, such as stainless steel and aluminum.

In another embodiment the present invention is directed towards a method for conducting security comprising the steps of providing a person to be screened with a screening cart wherein the screening cart is a frame assembly designed to physically complement the entry gate and internal configuration of an X-ray system; providing a guide mechanism that physically engages the screening cart wherein the guide mechanism directs the screening cart through an X-ray scanning system; delivering the screening cart to the passenger; indicating to a passenger to walk through a passenger screening device; delivering the screening cart to the passenger, after both passenger and cart have been screened; and integrating data collected from both X-ray scanning system and passenger screening device to generate overall threat assessment.

Preferably, the X-ray scanning system comprises a radiation source and a detector array. The radiation source is preferably a dual energy source. In one embodiment, the entrance of the X-ray source is a C-shaped structure. In one embodiment, a passenger screening device, such as but not limited to a metal detector, is provided.

In a preferred embodiment, the screening cart comprises a “C”-configuration assembly. Preferably, the “C”-configuration assembly screening cart further comprises a substantially connected frame assembly having a substantially rectangular base; a substantially rectangular drawer; and at least two wheels. Preferably, the substantially rectangular base and substantially rectangular drawer are integrally connected with a vertical arm to form a “C”-shaped assembly. Preferably, the cart is comprised of a metallic material, such as stainless steel and/or aluminum.

In another embodiment, the present invention is directed towards a system for conducting security, comprising an X-ray scanning system further comprising an entrance designed to physically complement a screening cart frame assembly; a guide mechanism to direct a screening cart passing through the X-ray scanning system; a passenger screening device; a mechanism for delivering the screening cart to the passenger after both passenger and cart have been screened; and an integrated screening station for integrating data collected from both X-ray scanning system and passenger screening device to generate overall threat assessment.

Preferably, the integrated screening station comprises a central server, further comprising a processor and a memory in data communication with the X-ray scanning system and the passenger screening device.

Preferably, the X-ray scanning system comprises a radiation source and a detector array. The radiation source is preferably a dual energy source. In one embodiment, the entrance of the X-ray source is a C-frame structure. In one embodiment, a passenger screening device, such as but not limited to a metal detector, is provided.

In a preferred embodiment, the screening cart comprises a “C”-configuration assembly. Preferably, the “C”-configuration assembly screening cart further comprises a substantially connected frame assembly having a substantially rectangular base; a substantially rectangular drawer; and at least two wheels. Preferably, the substantially rectangular base and substantially rectangular drawer are integrally connected with a vertical arm to form a “C”-shaped assembly. Preferably, the cart is comprised of a metallic material, such as stainless steel and aluminum.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the present invention will be appreciated, as they become better understood by reference to the following Detailed Description when considered in connection with the accompanying drawings, wherein:

FIG. 1 is a top perspective view of a functional layout of one embodiment of an integrated carry-on baggage cart and passenger screening station that facilitates the screening of both carry-on luggage placed on the screening cart and individual passengers;

FIG. 2 is a perspective view of one embodiment of carry-on baggage cart or screening cart configuration as used in the present invention;

FIGS. 3 a, 3 b, and 3 c illustrate various perspective views of a portion of a X-ray imaging system as used in the carry-on baggage cart screening portion of the integrated screening system of the present invention;

FIG. 4 depicts the X-ray imaging system inspection area entrance in an embodiment of the operation of the integrated carry-on cart and passenger screening station of the present invention; and

FIG. 5 is a top perspective view of an automated passenger X-ray metal detector in one embodiment of the integrated carry-on cart and passenger screening station of the present invention.

DETAILED DESCRIPTION OF THE INVENTION

The present invention is directed towards a high throughput screening system that improves the efficiency, technique, and quality of passenger and carry-on baggage scanning at secure locations. Although the system of the present invention has many applications, the preferred embodiment will be described with particular reference to its application to an airport security system. One of ordinary skill in the art would appreciate the present invention may be applied to a plurality of other security environments, including prisons, government buildings, other buildings requiring secured access, and entertainment venues.

As used here, the term “baggage” refers to any type of carry-on item as is conventionally allowed in various locations, including, but not limited to smaller sized luggage, laptop cases, purses, briefcases, umbrellas, handbags, large coats, and in some cases, shoes. Generally, these items are required to be removed from the individual prior to entrance into the metal detector area. In addition, while the terms “individual” and “passenger” are used interchangeably, it is to be understood by those of ordinary skill in the art that any living entity may be screened for any reason in the metal detector portion of the system of the present invention and constitutes an individual or passenger.

The screening system of the present invention comprises a plurality of screening devices, including, but not limited to, metal detectors, X-ray imaging systems, baggage trace detectors, trace portals, personnel scanners, X-ray diffraction systems, and personnel identification systems. In one preferred embodiment, the screening system of the present invention employs both a passenger metal detector system and a carry-on cart baggage scanning system. Thus, both the passenger and their baggage may be screened efficiently. In addition, the present invention optionally employs a method for integrating the information from the two detection sources, thus enabling a more accurate threat level determination.

More specifically, the present invention discloses novel methods, apparatuses, and systems facilitating screening of both individual passengers and their carry-on luggage carts thus improving the efficiency and throughput of the screening system. Preferably, the scan data from the carry-on baggage cart screening system and the individual passenger screening system are transmitted to a central server by any method known to one of ordinary skill in the art.

Optionally, the present invention may associate assessment data of two or more entities to evaluate the overall threat level of a plurality of entities, wherein the entity can be an individual or a bag. Simply evaluating the threat level associated with each individual based upon the metal content possessed by that individual may not be sufficient.

In current security systems, the X-ray screening system can be a bottleneck relative to the entire screening system. It takes a considerable amount of time for individuals to divest themselves of their personal belongings including shoes, coats, keys, and phones and to remove laptops from their cases for X-ray screening of these items. This series of operations tends to happen serially with everyone waiting in line until they have access to the machine and it is their turn to divest. This is followed by the need to reconcile the passenger items after screening that, again, creates delays in the check station flow.

Operationally, it is preferred that passengers are positively linked to their belongings, including luggage, bags, and other personal items. Personal belongings not subject to a baggage claim check or other tag may be linked to specific passengers by tagging each personal belonging at the security checkpoint or check station. It is preferred, however, to associate passengers with their belongings using a form of physical association. In one embodiment, a passenger divests themselves of personal belongings by placing all appropriate items into the first stage screening device, such as on the carry-on baggage cart, or screening cart, capable of passing through the X-ray screening machine via a floor conveying mechanism with guide rails. While the first stage screening device is conducting a scan on the passenger's carry-on baggage, that particular passenger is preferably directed to walk through the metal detector via a gate mechanism, which is further described in detail below. Succeeding passengers are prevented from taking any action by a gate or light. After the first individual and their belongings successfully pass through the first stage screening process and, accordingly, a second gate, light, or area, a subsequent individual is allowed to enter the first stage screening process.

The metal content of each belonging, such as electronics, batteries, wire, or other items, may be determined automatically by a computer process and is well known to those of ordinary skill in the art. Once the metal content is determined for each passenger and his or her belongings, the system can then sum the metal contents of all the baggage and/or items associated with the person. The system can then produce an overall threat score (indicating a likelihood of prohibited items), thereby leading to further investigation or heightened subsequent stage screening. This approach enables the identification of pieces of prohibited material, even if separated out onto in several different belongings.

Reference will now be made in detail to specific embodiments of the invention. While the invention will be described in conjunction with specific embodiments, it is not intended to limit the invention to one embodiment.

FIG. 1 illustrates a top perspective view of a functional layout of one embodiment of an integrated carry-on baggage cart and individual passenger screening station 100, facilitating the screening of both carry-on baggage placed on the cart and passengers. Integrated screening station 100 comprises a central server (not shown), which has a processor (not shown) and a memory (not shown) in data communication with at least two screening devices. In a preferred embodiment, the two screening devices comprise an X-ray imaging system 102, such as a C-frame X-ray imaging system, and passenger screening metal detector 103. X-ray baggage screening system 102 is designed to accept carry-on baggage carts, as will be described in further detail below. One of ordinary skill in the art can appreciate that a plurality of screening devices may be incorporated in the system without departing from the spirit and scope of the invention.

The processor can execute a plurality of different calculations, processes, and/or algorithms to evaluate the assessment data received from the plurality of devices. In one embodiment, the assessment data is evaluated according to a fuzzy logic algorithm based upon rules established governing the meaning of individual features. Alternately, a neural network may be employed to evaluate the data. Alternatively, the data may be evaluated by an automated classification system.

The abovementioned approaches of threat evaluation improve the level of security because data from multiple screening devices can be integrated to determine if a threat level exists. In particular, the integration of data from multiple screening devices aids in efficiently handling circumstances whereby an individual is cleared by each screening device independently but, in combination, represents a sufficient threat requiring subsequent analysis.

Passengers, once having entered integrated screening station 100, perform a few mandatory tasks, in part or wholly manual, including, but not limited to, acquiring a carry-on cart or screening cart 104, (described in greater detail with respect to FIG. 2) from a carry-on cart area 105 and subsequently loading carry-on cart 104 with personal belongings in loading area 106 for entrance into inspection area 107. Carry-on cart or screening cart 104 is screened through inspection area 107 via C-frame X-ray imaging system 102, described in greater detail below with respect to FIG. 3. Individual passengers are directed to walk through metal detector 103, which is also described in greater detail below with respect to FIG. 5.

Each screening device has an associated memory and processing power that is used to evaluate the threat level associated with an entity, being scanned or detected, and to determine the value of assessment data to be transferred preferably to central server and/or other devices. Thus, a central server optionally aggregates data received from the plurality of screening devices 102 and 103, and uses a set of pre-defined processes to determine the overall threat level associated with the scanned entity. Once determined, an alarm, status signal, or other threat indicator information is communicated to an indicator system (not shown). One of ordinary skill in the art would appreciate that the central server could optionally be physically combined with one of the screening devices and need not be independent or separate from any or all of the devices.

Assessment data is received by the central server from the employed screening devices, via a transceiver, into a memory. Preferably, each device, including X-ray imaging system 102, metal detector 103, and optional devices, such as but not limited to, a trace detector are capable of transmitting data in a real-time manner to the central server and/or every other device present in the system. The memory is in data communication with a processor capable of executing code to determine a total threat level based upon the individual device assessment data received. The memory and processor may be incorporated into one of the screening devices or be embodied in the central server that is in data communication with the plurality of screening devices.

Carry-on baggage cart 104 is designed to pass through the suitably designed C-frame X-ray imaging system 102 via a conveyance mechanism 108, such as, but not limited to a guide rail mechanism. If no item of threat or concern is detected in any of the screening devices, the carry-on baggage cart and/or passenger are cleared. Upon detection of an item of threat or concern, the entire carry-on baggage cart and/or passenger is tagged as suspect and taken to a designated search area, whereby the individual or carry-on baggage are subjected to further manual search. Subsequently, passengers off-load carts 104 in a designated area 109, away from the screening area, thereby preventing congestion. Eventually, carts are put back into use via the cart mover portion 110 of the conveyance mechanism.

In a preferred embodiment the carry-on baggage cart or screening cart is of a three-dimensional (3-D) configuration allowing it to fit and thus pass through an entry gate of the C-framed X-ray imaging system implemented in accordance with the present invention and as described in further detail with respect to FIG. 3. Preferably, the screening cart is substantially a frame assembly and designed to physically complement the entry gate and internal configuration of the X-ray system. In one embodiment, the carry-on baggage cart comprises a novel “C”-configuration that is complementary to a “C”-configured entry gate of the X-ray imaging system, thereby traversing the inspection area of the X-ray imaging system. A “C” configuration of the carry-on baggage cart also keeps the members or bars comprising the frame assembly of the cart away from the X-ray path, thus facilitating appropriate positioning of the carry-on items that are placed upon it. This, in turn, assists in accurate scanning of the contents of the carry-on baggage cart via X-ray, thus leading to the capturing, storing, processing and development of complete X-ray images.

Referring now to FIG. 2, a perspective view of one carry-on baggage cart as used in the present invention is depicted. Carry-on baggage cart 200 comprises a substantially connected frame assembly with substantially rectangular base 205 and substantially rectangular drawer (or bin or tray) 210, integrally connected by connecting vertical arm 215, thus forming a “C”-shape frame assembly. Preferably carry-on baggage cart 200 is of the following material and constructional specifications: rigid and lightweight metallic material such as, but not limited to, stainless steel or aluminum. A person of ordinary skill would appreciate that the materials used for the cart are not limited to the abovementioned metallic materials and can be easily adjusted to suit varied operational requirements and specifications.

Although cart 200 is preferably constructed in the form of a three-dimensional “C”-shape, a variety of other design approaches may be adopted for the construction of the carry-on baggage cart and its corresponding X-ray screening system and are readily apparent to persons of ordinary skill in the art.

In one embodiment, carry-on baggage cart 200 comprises a three-dimensional “C”-shaped frame assembly. Carry-on baggage cart 200 comprises base 205 and drawer 210 integrally connected by vertical connecting arm 215. Cart base 205 preferably comprises wheels 220 a, 220 b, 220 c, and 220 d. While it is preferred that carry-on baggage cart 200 is propelled via wheels, one of ordinary skill in the art would understand that any other conveyance mechanism may be employed in the present invention. Cart base 205 further comprises four side bars or members 205 a, 205 b, 205 c, and 205 d which are laterally connected to one another. Side members 205 a, 205 b, 205 c, and 205 d may optionally be connected to a floor base 205 e (not shown). Side members 205 a and 205 d are substantially parallel to each other. Side members 205 b and 205 c are substantially parallel to each other. Side member 205 a is substantially perpendicular to side members 205 b and 205 c. Side member 205 d is also substantially perpendicular to side members 205 b and 205 c, thus forming a rectangular base.

The bottom end 215 a of integrally connecting vertical arm 215 is connected to proximal side member 205 a of cart base 205, just above wheel 220 a. The top portion 215 b of connecting vertical arm 215 is fixably connected to drawer 210, at its proximal end 210 a. Drawer 210 has four side walls 210 a, 210 b, 210 c, and 210 d which are fixably and adjacently connected to one another. In addition, four side walls 210 a, 210 b, 210 c, and 210 d are integrally connected to drawer base 210 e. Drawer 210 may further be compartmentalized by an additional retaining wall, such as 210 f. Drawer 210 or parts thereof may optionally be removable for ease of loading and unloading carry-on items. In addition, drawer 210 may optionally comprise a lockable cover (not shown) for additional security of personal items. Drawer 210 is preferably rectangular in form, such as with cart base 205, wherein side walls 210 a and 210 d may be shorter in length than walls 210 b and 210 c, although a variety of shapes may be readily apparent to those of ordinary skill in the art.

FIGS. 3 a, 3 b, and 3 c illustrate various perspective views of the C-frame X-ray imaging system as used in the carry-on baggage screening portion of the integrated screening system of the present invention. As described with respect to FIGS. 3 a and 3 b, X-ray imaging system 300 comprises a radiation source 305 and an X-ray detector array 310. In one embodiment, the X-ray imaging system 300 employed is a backscatter detection type system. Depending on the design of the corresponding cart, radiation source 305 can be located either above or below the drawer of the carry-on cart shown in FIG. 2. The array of detectors is above or below the cart, also depending upon the placement of the radiation source 305. One of ordinary skill in the art would appreciate how to position a radiation source relative to a set of detectors.

In one embodiment, radiation source 305 is an X-ray generator. The source of radiation includes radio-isotopic source, an X-ray tube or any other source known in the art capable of producing beam flux and energy sufficiently high to direct a beam to traverse the space through the carry-on baggage cart and the contents of the cart to detectors at the other side. The choice of source type and its intensity and energy depends upon the sensitivity of the detectors, the radiographic density of the cargo in the space between the source and detectors, radiation safety considerations, and operational requirements, such as the inspection speed. One of ordinary skill in the art would appreciate how to select a radiation source type, depending upon his or her inspection requirements.

In an optional embodiment, the radiation source may be a dual energy radiation source which employs respectively different radiation energies or two detector systems, having varying sensitivities to differing radiation energies. By comparing at least two congruent radiation images that were obtained with respectively different radiation energies, it is possible to discriminate articles having low and high ordering number. Organic materials, such as drugs and explosives, can thus be better distinguished from other materials, for example metals (weapons).

While not shown in FIGS. 3 a, 3 b, and 3 c, X-ray imaging system 300 also comprises a floor conveyance mechanism, further comprising guide rails for accepting the wheel mechanism of the carry-on baggage cart, both of which are described in further detail below.

As shown in FIG. 3 c, the X-ray imaging system 300 comprises detector array 310. FIG. 3 c is a two-dimensional side perspective view of the X-ray imaging machine shown in FIG. 3 a. In one embodiment, detector array 310 is an “L”-shaped array, as shown. Detectors 310 may be formed by a stack of crystals that generate analog signals when X-rays impinge upon them, with the signal strength proportional to the amount of beam attenuation in the object under inspection. In one embodiment, the X-ray beam detector arrangement consists of a linear array of solid-state detectors of the crystal-diode type. A typical arrangement uses cadmium tungstate scintillating crystals to absorb the X-rays transmitted through the OUI and to convert the absorbed X-rays into photons of visible light. Crystals such as bismuth germinate, sodium iodide, or other suitable crystals may be alternatively used as known to a person of ordinary skill in the art. The crystals can be directly coupled to a suitable detector, such as a photodiode or photo-multiplier. The detector photodiodes could be linearly arranged, which through unity-gain devices, provide advantages over photo-multipliers in terms of operating range, linearity and detector-to-detector matching. In another embodiment, an area detector is used as an alternative to linear array detectors. Such an area detector could be a scintillating strip, such as cesium iodide or other materials known in the art, viewed by a suitable camera or optically coupled to a charge-coupled device (CCD).

Referring to FIG. 4, the operational aspects of the inspection area entrance in a preferred embodiment of the integrated carry-on cart and passenger screening station 400 (not shown in its entirety) of the present invention is illustrated. An exemplary carry-on baggage cart or screening cart 404 of the present invention is shown just before it is guided via guide rail conveyance mechanism 401 into the entrance 403 of the X-ray imaging system 402. The entrance 403 is preferably formed in the same shape as its corresponding screening cart 404. In one embodiment, the entrance to the X-ray imaging system 402 defines a “C”-shaped opening so that the preferred “C”-shaped carry-on baggage cart design, described with respect to FIG. 2 above, is easily guided through the system via guide rail conveyance mechanism 401.

Guide rail conveyance mechanism 401 preferably includes structural rail members placed laterally opposite from one another. Structural rail members preferably comprise protrusions or fingers for physically attaching to the carry-on baggage cart at its distal end 405 to pull the cart through the inspection aperture of X-ray imaging system 402. Thus, the wheels of the carry-on baggage cart are guided through the conveyance mechanism via a guide-rail system with propelling fingers when the scanning process begins. The conveyor speed is controlled to ensure proper resolution of the scanned item when being projected on the operator monitor. One of ordinary skill in the art would appreciate that a variety of conveyance mechanisms can be employed including, conveyor belts, arms, extensions, or any other type physical attachment mechanism for automatically attaching to a cart and moving the cart through the X-ray system.

After a passenger loads his or her items onto the carry-on baggage cart, the individual provides loading indications to the system. Such loading indications may be varied, depending upon the operational requirements of the system. In one embodiment, the loading indication is provided by the passenger or the operator pressing a button provided within each loading area. Once depressed, the button advances the carry-on baggage cart through the guide rail system.

In another embodiment, the system employs an electronic mat that automatically signals the start and end of loading the carry-on baggage cart to the system using the weight and exerted pressure by cart and/or individual using the system.

In another embodiment, the system requires the user to swipe a magnetic boarding card to signal the start and/or finish of loading through card reader machines [not shown] installed at each of the loading areas. Using this technique, the system can track the owner of the items that are deposited for scanning.

Upon receiving a loading indication, the guide rail conveyance mechanism 401 attaches, receives, acquires or snags, via its protusion(s), the leading edge of the cart 404, and pulls it toward the entrance 403 through X-ray imaging system 402 for screening. The guide rails direct the wheels of the cart 404 through the interior sidewalls of the X-ray imaging system 402. The length and speed of the guide rail conveyance mechanism 401 is chosen so as to give optimum time to the operators to make a decision.

As described with respect to FIG. 3 above, the X-rays are filtered and collimated as they are emitted from the radiation source (not shown in FIG. 4). Subsequently, these rays pass through the contents of the carry-on baggage cart and are then detected by the X-ray detectors (not shown in FIG. 4). The X-rays are then captured by an image intensifier and displayed on a monitor. Further, the captured image is stored in a memory for later processing in order to develop a final image. In one embodiment, the images may be viewed by security personnel. In another embodiment, the images may be pre-screened by a computer using mathematically based image processing algorithms. In the event the computer does not detect a threat, the cart is cleared. If a potential threat is detected, then the image is sent to a workstation where security personnel can view the image and make a determination of whether the articles in the cart need to be hand searched.

Once scanned, the guide rail conveyance mechanism 401 delivers the scanned carry-on baggage cart 404 to a designated collection point. The collection point may be designated by an operator or controlled automatically and is preferably away from the screening area to avoid congestion. In addition, the collection point may comprise a designated search area for those passengers requiring additional searching, where security personnel perform a manual search of the passenger and their carry-on items. To aid the security personnel in manual searching of items, the X-ray or optical images of the items are displayed on a plurality of search screens, in front of the security personnel. In the preferred embodiment, an operator console is present within the designated search thereby assisting the security personnel to optionally change the display format or orientation of the images displayed on the search screens.

In one embodiment, the operator is given a predetermined time period to inspect the items, after which the system routes the items to a predetermined default, which can be either towards designated area for off-loading carts or towards designated search area, depending on the system settings.

In one embodiment, operators, controlling the system via an operator workstation, can inform users from which designated collection area the individual can retrieve his or her cart containing belongings. One of ordinary skill in the art can appreciate that the selection of site regarding installation of the operator workstations can be made depending upon the specific operational requirements. For instance, and by no way of limitation, operator workstations may preferably be installed either near the X-ray imaging system 402 or remotely located and controlled in a different room entirely. The location and placement of operator workstations does not impose any restriction on the invention itself.

In another embodiment, the system is controlled by a software system that determines the collection point to which the items will be delivered after scanning.

In one embodiment, all the entry points (or X-ray lanes) are assigned a unique number, and each entry point will have a corresponding collection point. Items transferred to the guide rail conveyance mechanism 401 through a particular entry point will be made available only on the collection point corresponding to that entry point. The numbers of each entry point and collection point will be displayed to the users.

In another preferred embodiment, the system requires the user to swipe the boarding card, through card reader machines installed at the collection points, before collecting the scanned items. Thus, the system further ensures authenticity of the users before yielding the scanned items. In addition, the system thus prevents the loss of articles due to theft or mistake.

In one embodiment, instead of collecting the scanned items from the collection point corresponding to the entry point used for depositing the items, the user can collect his items from any collection point by swiping his boarding card through the machine installed at that collection point. The term “scanned item”, as used here refers to the carry-on baggage cart with passenger belongings that have been subjected to a scan, but it not limited to such interpretation.

As described with respect to FIG. 5 below, metal detectors and/or trace detectors are employed in the integrated system of the present invention and are used to scan individuals and passengers after they have deposited their belongings for X-ray scanning via the carry-on baggage cart screening system. FIG. 5 is a perspective view of an automated passenger X-ray metal detector in a preferred embodiment of the present invention. Metal detector 500 is automated to include a controlled entry gate 501 and a controlled exit gate 502. The exit gate is controlled to open upon approach by a passenger as long as the passenger does not trigger an alarm. Upon detection of a threat or item of concern on the body of a passenger as he walks through and under the defined opening 503 of metal detector, the passenger is tagged as suspect and simultaneously an alarm, status signal, or other threat indicator information is communicated to an indicator system 504. Thereafter, the passenger is directed towards a designated search area by a dedicated operator, where the passenger is manually searched by security personnel.

Metal detector 500 may preferably comprise an associated processor 505 (not shown) and a memory 506 (not shown). Optionally, metal detector 500 has an embedded counter incorporated into processor 505 that records and stores the number of people that pass through the metal detector 500 in a given period of time.

In another embodiment, a trace portal may screen passengers. Detection of certain trace materials, including, for example, explosives, contraband traces, or traces of materials that are not contraband but may be associated with contraband or other prohibited activities, such as gun oil, may be used to enhance the security level of the other systems.

In another embodiment, the screening system of the present invention comprises a plurality of screening devices, including, but not limited to, metal detectors, carry-on baggage cart systems as described below, X-ray imaging systems, baggage trace detectors, trace portals, personnel scanners, quadrupole resonance systems, X-ray diffraction systems, and personnel identification systems. The screening devices are optionally in data communication with at least one other screening device and/or a central server. The present invention may include two or more different devices and is not limited in the number or diversity of devices utilized. Data from a plurality of the devices may optionally be integrated to provide a complete picture of the threat level associated with an individual or a baggage, as opposed to being solely evaluated at each device.

In one embodiment, each screening device has an associated memory and processing power that is used to evaluate the threat level associated with an entity, being scanned or detected, and determine the value of assessment data to be transferred preferably to other devices. For example, a passenger screening metal detector may compare obtained scan information with image data stored in memory to determine the threat level associated with an entity and, accordingly, determine the value of assessment data.

Screening devices while in communication exchange information comprising assessment data including, but not limited to, information that provides a quantitative or qualitative assessment of how insecure a detected or screened entity, such as a passenger or a bag, may be. The assessment data is preferably more than a binary alarm indicator. In one embodiment, the assessment data is a numerical value on a scale of ten that corresponds to a specific threat level. The scales for evaluating the threat level can be developed for each device based on prior experience. It must be noted that the design, calibration, and use of such scales, such as those mentioned in the evaluation of threat level of an entity, are routine undertakings of engineering for those of ordinary skill in the art having the benefit of this disclosure consequently they will not be further detailed herein.

In one embodiment, the comparison of obtained scan information with image data stored in memory followed by evaluation of threat level and subsequent determination of assessment data may preferably comprise of cases including, but not restricted to, first, second, and third case etc. in that order, depending upon distinct circumstances arising therein plus corresponding actions taken for the same. Firstly if, for example, the X-ray screening system associates scan data with images resembling objects including, but not limited to, guns, cartridges, weapons, or other dangerous items etc. It can assign a high threat value to the scanned entity and, accordingly, generate assessment data that, regardless of the other assessment data generated by other devices, would trigger an alarm. Secondly if, for example, the X-ray screening system associates scan data with images that resemble low threat items, such as elongated structures or metallic boxes, it can assign a lower threat value to the scanned entity and, accordingly, generate assessment data that may, in combination with assessment from other devices, trigger an alarm. Lastly if, for example, the X-ray system associates scan data with images that resemble negligible threat items, such as clothing, it can assign a minimal threat value to the scanned entity and, accordingly, generate assessment data that will not trigger an alarm.

The above examples are merely illustrative of the many applications of the system of present invention. Although only a few embodiments of the present invention have been described herein, it should be understood that the present invention might be embodied in many other forms without departing from the spirit or scope of the invention. Therefore, the present examples and embodiments should be considered as illustrative and not restrictive, and the invention may be modified within the scope of the appended claims. 

1. A method for conducting security comprising the steps of: providing a person to be screened with a screening cart wherein the screening cart is a frame assembly designed to physically complement an X-ray scanning system; providing a guide mechanism that physically engages the screening cart wherein the guide mechanism directs the screening cart through an X-ray scanning system; and delivering the screening cart to the passenger.
 2. The method of claim 1 further comprising the step of directing a passenger to walk through a passenger screening device.
 3. The method of claim 2 wherein the passenger screening device is a metal detector.
 4. The method of claim 1 further comprising the step of receiving from a passenger an indication that the passenger is ready to be screened.
 5. The method of claim 1 wherein the screening cart comprises a “C”-configuration assembly.
 6. The method of claim 5 wherein the “C”-configuration assembly screening cart further comprises: a substantially connected frame assembly having: a substantially rectangular base; a substantially rectangular drawer; and at least two wheels wherein said substantially rectangular base and said substantially rectangular drawer are integrally connected with a vertical arm to form a “C”-shape assembly.
 7. The method of claim 1 wherein the cart is comprised of a metallic material.
 8. The method of claim 7 wherein the metallic material includes at least one of stainless steel and aluminum.
 9. The method of claim 1 wherein the X-ray scanning system comprises a radiation source and a detector array.
 10. The method of claim 9 wherein said radiation source is a dual energy source.
 11. The method of claim 1 wherein the entrance of said X-ray source complements a C-frame structure.
 12. A system for conducting security comprising; an X-ray scanning system further comprising an entrance designed to physically receive a screening cart frame assembly; and a guide mechanism to direct a screening cart through the X-ray scanning system and to the passenger after the cart has been screened.
 13. The security system of claim 12 wherein said X-ray scanning system comprises a radiation source and a detector array.
 14. The security system of claim 13 wherein said radiation source is a dual energy source.
 15. The security system of claim 12 further comprising a passenger screening device.
 16. The security system of claim 15 wherein the passenger screening device is a metal detector.
 17. The security system of claim 12 wherein the screening cart comprises a “C”-configuration assembly.
 18. The security system of claim 17 wherein the “C”-configuration assembly screening cart further comprises: a substantially connected frame assembly having: a substantially rectangular base; a substantially rectangular drawer; and at least two wheels wherein said substantially rectangular base and said substantially rectangular drawer are integrally connected with a vertical arm to form the “C”-shape assembly.
 19. The security system of claim 12 wherein the cart is comprised of a metallic material.
 20. The security system of claim 19 wherein the metallic material includes at least one of stainless steel and aluminum.
 21. The security system of claim 12 wherein the entrance of said X-ray source is a C-shaped structure.
 22. A method for conducting security comprising the steps of: providing a person to be screened with a screening cart wherein the screening cart is a frame assembly designed to physically complement the entry gate and internal configuration of an X-ray system; providing a guide mechanism that physically engages the screening cart wherein the guide mechanism directs the screening cart through an X-ray scanning system; indicating to a passenger to walk through a passenger screening device; and delivering the screening cart to the passenger, after both passenger and cart have been screened.
 23. The method of claim 22 wherein the passenger screening device is a metal detector.
 24. The method of claim 22 wherein the screening cart comprises a “C”-configuration assembly.
 25. The method of claim 24 wherein the “C”-configuration assembly screening cart further comprises: a substantially connected frame assembly having: a substantially rectangular base; a substantially rectangular drawer; and at least two wheels wherein said substantially rectangular base and said substantially rectangular drawer are integrally connected with a vertical arm to form the “C”-configuration assembly.
 26. The method of claim 22 wherein the screening cart is comprised of a metallic material.
 27. The method of claim 26 wherein the metallic material includes at least one of stainless steel and aluminum.
 28. The method of claim 22 wherein the X-ray scanning system comprises a radiation source and a detector array.
 29. The method of claim 28 wherein said radiation source is a dual energy source.
 30. The method of claim 22 wherein the entrance of said X-ray source is a C-frame structure.
 31. The method of claim 22 further comprising the step of integrating data collected from both X-ray scanning system and passenger screening device to generate a threat assessment.
 32. A system for conducting security comprising: an X-ray scanning system further comprising an entrance designed to physically complement a screening cart frame assembly; a guide mechanism to direct a screening cart through the X-ray scanning system and to the passenger; a passenger screening device; and an integrated screening station for integrating data collected from both X-ray scanning system and passenger screening device to generate a threat assessment.
 33. The system of claim 31 wherein said integrated screening station comprises a central server, further comprising a processor and a memory in data communication with the X-ray scanning system and the passenger screening device.
 34. The system of claim 31 wherein the passenger screening device is a metal detector. 